ITMI20090543A1 - DUPLEXER FILTER IN A RECTANGULAR WAVE GUIDE INCLUDING A DIVERSE AXIAL STRIP COMMON TO CAVITIES AND IRIDS FOR THE VARIATION OF TUNING BY ROTATION - Google Patents

Description

the element of variation of tuning lying completely inside the resonant cavities and irises, and being able to assume different widths in correspondence with the cavities and irises;

the element of tuning variation having the extremities hinged inside respective axial holes present in the walls that delimit the terminal cavities; the element of tuning variation having maximum width within the cavities and the irises such as to be able to rotate 360 ° without touching the

, as also described in claim 1.

Further characteristics of the present invention considered innovative are described in the dependent claims

Advantageously, the tuning variation element allows the tuning of the central frequency of the filter to be varied over a frequency range higher than the passband of the filter. From the geometric point of view

the element of tuning variation is such that, considering any cross section of the filter, it can be inscribed in a circle with a center in the longitudinal axis and with a diameter smaller than the diameter of a concentric circle on whose circumference they lie two diametrically opposite points of the inner contour of the resonant cavity, or deHâ € ™ irìde, depending on where the section is taken.

According to the invention, the element of tuning variation, due to the shape or the different permeability to electric or magnetic fields of its component parts, is able to determine an average permeability within the generic resonant cavity which varies with the angle of rotation of the aforesaid element about its own longitudinal axis. Since the field lines assume stationary configurations within the resonant cavities, the variation in average permeability is necessarily periodic and is repeated at each complete rotation, or fraction of the round angle, depending on the symmetry that the component parts have with respect to the field configuration.

According to the invention, the terminal cavities are coupled to a respective bent or curved waveguide section for the introduction or withdrawal of the signal, since the oblique walls are crossed by the said axial holes that pivot the ends of the tuning variation element, one end of which is mechanically connected to a manually operated or electronically controlled precision angle actuator.

Claims (18)

R I V E N D I C A Z I O N I 1. Tunable microwave band-pass filter (1, 60), comprising a waveguide section with inside a series of transverse walls (41) equipped with coupling irises (42) aligned along the longitudinal axis (Asini) to delimit adjacent resonant cavities (43), the filter including a longitudinal element of tuning variation common to all resonant cavities, characterized by the fact that: the waveguide section is made up of two half-shells (1a, 2a) mating along the edges (1b, 2b); - the element of variation of tuning (EVS1, 44, 45) lying completely inside the resonant cavities (43) and the irises (42), and having different widths in correspondence with the cavities and irises; the tuning variation element having the pivotal ends within respective axial holes (6, 7) present in the walls that delimit the terminal cavities (4, 5); the tuning variation element (44, 45) having a maximum width within the cavities (43) and the irises (42) such as to be able to rotate 360 ° without touching the walls. 2. The filter of claim 1, characterized by the fact that the tuning variation element (EVS1, EVS2a / b / c), due to the shape or the different permeability to electric or magnetic fields of its component parts, determines, with respect to the stationary configuration of said fields, an average permeability within the generic resonant cavity (43) variable with the angle of rotation of the aforesaid element around its own longitudinal axis (Asini). 3. The filter of claim 1, characterized by the fact that the terminal cavities are coupled to a respective bent or curved waveguide section (4, 5) for the introduction or withdrawal of the signal, since the walls are oblique crossed by said axial holes (6, 7) which pivot the ends (14, 15) of the tuning variation element (EVS1), one end of which (15) is mechanically connected to a manually operated precision angular actuator ( 20) or electronically controlled (35). 4. The filter of claim 1, characterized in that the resonant cavities are divided into two groups (risi-ris2; ris3-ris5) by a T junction (63) whose common mouth is crossed by two signals having frequency disjoint within the tuning range, a first group of cavities (ris1-rìs2) constituting a first band pass filter (61) for the first signal, a second group of cavities (ris3-ris5) constituting a second band pass filter (62) for the second signal; the tuning variation element (EVS4) crossing the horizontal section of the T-junction. 5. The filter of claim 4, characterized by the fact that the tuning variation element (EVS4) is truncated at the T junction (83) to form two independent elements (EVS5, EVS6), and the said junction (83) including a support (86) with two holes for the introduction of the ends of the two elements derived from the truncation (EVS5, EVS6) without them touching, thus allowing the independent rotation of the two elements to vary the tuning, the other ends of which protrude from the end walls of the filter (80) for connection to a respective precision angular actuator (89, 90). 6. The filter of claim 1, characterized in that said tuning variation element (EVS1) is a strip of constant thickness and width within each cavity and each iris. 7. The filter of claim 6, characterized in that said tuning variation element is provided with through or blind holes to obtain the desired average permeability value. 8. The filter of claim 6, characterized in that said tuning variation element (EVS1) comprises at least another mating strip of different permeability to electric or magnetic fields. 9. The filter of claim 6, characterized in that said tuning variation element comprises a plurality of parallel strips spaced from each other. 10. The filter of claim 1, characterized in that said tuning variation element (EVS2a) is a strip of constant thickness and variable width within the cavities, maintaining a specular profile with respect to the longitudinal axis. 11. The filter of claim 10, characterized in that said tuning variation element (EVS2a) has a profile which reflects half the period of a sinusoid. 12. The filter of claim 1, characterized in that said tuning variation element (EVS2b) is a longitudinally slotted cylinder within the resonant cavities. 13. The filter of claim 1, characterized in that said tuning variation element (EVS2c) is a cylinder with longitudinal openings with walls converging within the resonant cavities. 14. The filter according to any one of the preceding claims, characterized in that said tuning variation element (EVS1) is constituted by dielectric material. 15. The filter according to any one of claims 1 to 13, characterized in that said tuning variation element (EVS1) is made of metallic material. 16. The filter according to any one of claims 1 to 13, characterized in that said tuning variation element (EVS1) is made up of parts in dielectric material and parts in metallic material. 17. The filter of claim 16, characterized by the fact that the tuning variation element (EVS1) is constituted by a dielectric strip or bar comprising metallizations in the shape of lines or circles, located inside or on the surfaces sideways or in both positions. 18. The filter according to any one of the preceding claims, characterized in that it is made in a rectangular waveguide (1) with the said resonant cavities (43) operating in the fundamental resonant mode TE101.